DE2827166A1 - Hot water preparing circuit - has tank enclosing refrigerator condenser coil to feed several users - Google Patents

Abstract

The hot water preparing plant uses refrigerant circuit consisting of evaporator, compressor, condenser and restrictors. The water to be heated draws heat from the condensing refrigerant. A number of user circuits can be connected to the single condenser. The condenser is designed as a storage container for the water to be heated. This tank accommodates a helical tube connected at the top with the outlet of the compressor. The outlet at the bottom is connected with the inlet of the restrictor. The hot water using circuit is connecterd to the tank.

Description

A 3303 June 14, 19 78

vo / poe

2027166

Helmut Genkinger
Grundstrasse 13

7293 Pfalzgrafenweiler

Hot water system

The invention relates to a hot water system with an evaporator, compressor, condenser and throttle element again refrigerant circuit leading to the evaporator, in which the refrigerant is generated by means of the available heat is evaporated in the evaporator and the water to be heated by means of the heat released in the condenser when the refrigerant is liquefied.

Such a hot water system has a refrigerant circuit, which works on the principle of the compression heat pump. The refrigerant with suitable thermodynamic properties is kept in the evaporator at such a pressure that the evaporation temperature is below the temperature of the one to be cooled Material is, which the heat to

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Provides. This temperature difference arises a heat flow in the evaporator and the refrigerant evaporates while absorbing heat. The resulting vapors are sucked off by the compressor and compressed to such a high pressure that the condensing temperature associated with this pressure is above the temperature of the water to be heated. Due to this temperature difference, the Heat is removed from the condenser and the entire refrigerant vapor is liquefied, releasing heat. The liquid one The refrigerant is then expanded in the throttle device to the low evaporator pressure and can thus be used in the evaporator absorb heat again. The refrigerant circuit is thus closed.

In the known hot water systems, the water to be heated is in the condenser through a coil or a Pipe system, which is heated by the condenser coil. The condenser coil can also do this run in the pipe coil. This structure of the condenser only brings one consumer circuit for the heated one Water. Should several consumer groups with different warm water are fed, then several condensers are to be connected in series, with each condenser controls its own group of consumers. This additional expenditure on condensers is considerable and, moreover, the The performance of the condenser connected in series is fixed. Such a plant® is for a hot water system for one or more hot water heating circuits and one Hot water consumer kras therefore not suitable, <ä.h * not optimal, since the demand in the hot water consumer circuit is not is continuous · An appropriately designed storage tank with regulation for each Verbsrauciherkreis would be for an economic one Operation inevitable.

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It is the object of the invention to design a hot water system of the type mentioned in such a way that in a simple manner Several consumer circuits with different water temperatures can be branched off at the single condenser and also the storage or buffering of heat at different temperatures in the same simple way can be done.

This object is achieved in that the Condenser is designed as a storage container for the water to be heated that a coil in the container is arranged upright, with its upper inlet with the outlet of the compressor and with its lower outlet with the Input of the throttle element is connected that at least one consumer circuit for heated water is connected to the container is and that utilizing the overheating heat of the refrigerant in the upper part of the coil Part of the water can be heated to a higher temperature for a consumer price with warmer water.

The various consumer groups are with this condenser structure about the water content of the container with each other coupled, so that the services of the various consumer groups can still vary. It turns out in Container under the influence of the temperature gradient in the water the container is always in a corresponding state of equilibrium.

For the consumer circuit with the heated water, the superheating heat of the refrigerant vapor is used when it enters the condenser pipe coil, so that part of the water in the upper area of the container can be heated to a higher temperature. The other consumer circuits are connected directly to the tank and receive the less warm water. These consumer circuits feed heating

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body or the like., During the substantially from the overheating higher heated water content is used e.g. as hot water for the hot water pipes.

According to one embodiment it is provided that the higher Temperature to be heated water housed in an insert container which is enclosed by the upper region of the pipe coil. In this way, heating water and Clearly separate service water from one another, but heat them to different temperatures in the single condenser.

In order to preheat the cold water supplied to the insert container, it is provided according to one embodiment that from this Insert container leads off a drain line for warmer water and that the inflowing cold water via an im The heat exchanger arranged in the lower region of the container can be fed to the inflow line of the insert container. Is this According to a further embodiment, the heat exchanger is enclosed by the lower region of the pipe coil, and then the subcooling occurs of the refrigerant in the liquid phase is also used to preheat the cold water which is supplied to the insert container is supplied for greater heating.

Since a temperature gradient develops in the water in the container from top to bottom, there is the possibility of an to connect different consumer circuits to the container at different heights. The drain line is always located higher than the reflux line. The consumer circuits then receive water at different temperatures.

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According to a further development it is provided that further heat exchangers are arranged in the lower area of the container, those for supplying external heat to the water to be heated in the container or for removing heat from the heated one Water in the container can be used. In this way, additional external heat sources can be used to heat the Take advantage of the water in the tank or the water of an external circuit can be heated. For an intimate Heat exchange is provided that at least a part of this heat exchanger from the lower region of the pipe coil is enclosed.

The efficiency of the refrigerant circuit can be further improved by leaving the liquid refrigerant the condenser coil is routed through a heat exchanger built into the evaporator. This is in addition to the recovery The heat from the liquid refrigerant also increases the volumetric refrigeration capacity during evaporation of the refrigerant reached.

The overheating heat of the refrigerant is sufficient in extreme conditions not off, the water supply for the hot water consumer circuit with a higher temperature is fully set to the desired level To heat temperature, then it can also be provided that the water in the insert container by means of an electrical Heating device can also be heated.

In contrast to known hot water systems, according to a particularly advantageous embodiment in the refrigerant circuit uses a refrigerant that heats up strongly when it is compressed. In this way the heat demand for warming is of the domestic hot water to a higher temperature in most cases without an additional electrical heating device reach.

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For a satisfactory and consistent operation of the single condenser for the various consumer groups with differently heated water is provided according to a further embodiment that the contents of the container and the connection cross-sections of the drain lines and the return lines of the consumer circuits designed so large are that in the circulation of the heated water in the consumer circuits in the tank, the temperature gradient is maintained as unchanged as possible in the heated water.

The invention is based on an embodiment example shown schematically in the drawing of a solar collector fed hot water heating system explained in more detail, which also heated to a higher temperature hot water domestic water can deliver.

In the hot water heating system according to the embodiment, a solar collector SK is used to heat water, The heated water is set in circulation via the opened valves V1 and V2 with the aid of the circulation pump P1. The main part of the heated water is fed to the inlet circuit of the evaporator VD with the help of the mixing valve MV1. The output circuit of the evaporator VD, which is acted upon by the refrigerant, leads via the compressor KD and the line L3 to a pipe coil HS arranged upright in a container B. The lower outlet of the pipe coil HS leads via the heat exchanger in the evaporator to the inlet of the throttle element DR. The outlet of the throttle element DR leads to the Output circuit of the evaporator VD, so that the refrigerant circuit is closed according to the structure of a compression heat pump.

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sen is. In the evaporator VD, the refrigerant is extracted from the heated water in the solar collector loop evaporates. The refrigerant vapor is brought to high pressure in the compressor KD and in the condenser VF, the refrigerant vapor is liquefied while releasing heat. The heat is transferred to the inside of the container B released water. Since a refrigerant is used that heats up strongly when it is compressed, it is produced in the upper turns of the pipe coil HS an increased temperature which is above the condensation temperature of the refrigerant lies. This allows a smaller amount of water to be heated to a higher temperature.

For this reason, an insert container EB is placed in the upper region of the container B, which is separated from the upper windings the pipe coil HS is enclosed. The cold water K is this insert container EB via a heat exchanger VW1 supplied, which is enclosed in the lower region of the container B by the lower turns of the coil HS. That Cold water is preheated via this heat exchanger VW1 and via line L3 of the inflow line ZL of the insert container EB supplied, which ends near the bottom of the insert container EB. The discharge line AL of the insert container EB leads to Withdrawal point E for hot water with a higher temperature. This The hot water consumer circuit feeds the hot water service water pipes of the heating system. For extreme conditions the water in the insert container EB can be additionally heated if required by means of an electrical heating device ZH will.

The refrigerant liquefies in the standing pipe coil HS, so that there is a temperature gradient from top to bottom.

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occurs, which is also transferred to the water in container B. As lines L4 and L5 show, a heating consumer circuit can be connected directly to container B with the heating element HK. The drain line L4 is above the Return line L5 arranged. With the mixing valve MV2 the heat flow can be regulated via the radiator HK. Complete the valves V3 and V4 with the circulation pump P2 the heating consumer circuit. The temperature of the water in this consumer circuit depends on the height of the drain pipe L4 on container B. In this way, other consumer circuits can also be connected to container B at different heights connect, the temperature of the circulating water increasing with the height of the drain line L4 increases at container B.

Like the heat exchanger housed in the lower part of tank B. VWZ shows, this heat can be fed directly to the storage tank and to the Warming can be used.

Further heat exchangers, e.g. VW3, can be accommodated in the lower area of container B, some of which are also supplied by the lower turns of the coil HS can be enclosed. These heat exchangers can optionally be used for supply of external heat to the water of the container B or for the extraction of heat from the heated water of the container B used for an external consumer circuit VK or the like will.

The condenser in this form includes a hot water boiler / which utilizes the overheating of the

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condensed refrigerant vapor directly to a hot water service water with a temperature that is above the temperature of the container B directly connected Main consumer circles.

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Claims (12)

Expectations \ λ). Water heater with an evaporator, compressor, condenser and flow control back to evaporate leading refrigerant circuit in which the refrigerant is evaporated by means of the available heat in the evaporator and the water to be heated is heated in the condenser while liquefying the refrigerant heat released by means of, characterized characterized in that the condenser (VF) is designed as a storage container (B) for the water to be heated, that in the container (B) a pipe coil (HS) is arranged upright, which with its upper inlet to the outlet of the compressor (KD) and its lower outlet is connected to the inlet of the throttle element (DR), that at least one consumer circuit (HK) for heated water is connected to the container (B) (L4, L5) and that utilizing the overheating of the refrigerant in the upper area the pipe coil (HS) a part of the water at a higher temperature for a consumer circuit (E) with heat er water can be heated. 2. Hot water system according to claim 1, characterized in that the water to be heated to a higher temperature is housed in an insert container (EB) which is enclosed by the upper region of the coil (HS). 3. Hot water system according to claim 2, characterized in that from this insert container (EB) a drain line (AL) goes off for warmer water and that the 809881/0233 ORDINAL incoming cold water (K) via one in the lower area of the container (B) arranged heat exchanger (VW1) of the inflow line (ZL) of the insert container (EB) can be fed is. 4. Hot water system according to claim 3, characterized in that the heat exchanger (VWl) is enclosed by the lower region of the coil (HS). 5. Hot water system according to one of claims 1 to 4, characterized / that on the container (B) different consumer circuits (HK) are connected at different heights, wherein the drain line (L4) is always higher than the return line (L5). 6. Hot water system according to one of claims 1 to 5, characterized in that further heat exchangers (eg VW2 and VW3) are arranged in the lower region of the container (B) which are used to supply external heat
the water to be heated in the container (B) or for the extraction of heat from the heated water in the container
(B) are usable. 7. Hot water system according to claim 6, characterized in that at least part of this heat exchanger (eg VW3) is enclosed by the lower region of the coil (HS). 8. Hot water system according to one of claims 1 to 7, characterized in that the lower outlet of the coil (HS) is connected to the inlet of the throttle element (DR) via an "additional exchanger (ZS) in the evaporator (VD), 909801/0 9. Hot water system according to one of claims 1 to 8, characterized in that the water in the insert container (EB) can be additionally heated by means of an electrical heating device (ZH). 10. Hot water system according to one of claims 1 to 9, characterized in that at least part of the heat obtained by a solar collector (SK) can be conducted directly via a heat exchanger (eg VW2) in the container (B) and the water in the container (B) can be preheated over it. 11. Hot water system according to one of claims 1 to 10, characterized in that a refrigerant is used which heats up strongly during compression. 12. Hot water system according to one of claims 1 to 11, characterized in that the contents of the container (B) and the connection cross-sections of the discharge lines (L4) and the return lines {L5) of the consumer prices (HK) are designed so large and accordingly designed that During the circulation of the heated water in the consumer circuits (HK) in the container iB) the temperature gradient in the heated water is maintained unchanged as far as possible. 909881/0233